An apparatus for determining the thickness of media is provided and includes a ferrous plate, a solenoid mounted perpendicular to the ferrous plate, and a magnet at the end of the solenoid piston. The solenoid piston ranges from a retract position to a down position where the magnet presses on media fed in the gap between the solenoid piston and the ferrous plate. A current source connected to the solenoid moves the piston to the retract position when the current source is energized. A detector is provided to determine when the solenoid piston is in the retract position. A programmable device controls the current source and a time measurement device. The programmable device simultaneously starts the time measurement device and increases current to the solenoid, thereby retracting the piston and timing the retraction.

Patent
   10731963
Priority
Jan 09 2018
Filed
Jan 09 2018
Issued
Aug 04 2020
Expiry
Jul 09 2038
Extension
181 days
Assg.orig
Entity
Large
1
632
currently ok
17. A method for automatic media thickness detection, comprising:
positioning a magnet mounted on a solenoid piston above a ferrous plate in a retract position, the solenoid being mounted so that the piston motion is perpendicular to the ferrous plate;
placing media between the ferrous plate and the magnet in the retract position;
pushing the magnet to a down position such that the magnet clamps the media to the ferrous plate;
retracting the magnet to the retract position;
measuring the time for the piston to reach the retract position from the down position;
correlating the measured time to known distance values; and
determining the thickness of the media based on the correlating step.
1. An apparatus for determining the thickness of media, comprising:
a ferrous plate;
a solenoid with a solenoid piston mounted above the ferrous plate, the solenoid piston motion being perpendicular to the ferrous plate;
a magnet disposed on an end of the solenoid piston proximate to the ferrous plate;
the solenoid piston having a range of motion between a retract position where the magnet is a predetermined distance above the ferrous plate, the predetermined distance providing a gap to feed media between the solenoid piston and the ferrous plate and a down position where the magnet presses on media fed in the gap between the solenoid piston and the ferrous plate;
an electrical energy source connected to the solenoid;
the solenoid piston being forced with a retracting force to the retract position when the electrical energy source energizes the solenoid to a predetermined level;
the solenoid piston having a bias element to keep the solenoid piston in the down position when the electrical energy source is not energizing the solenoid;
a detector configured to determine when the solenoid piston is in the retract position; and
a programmable device in communication with the detector, the programmable device controlling the electrical energy source;
wherein, the electrical energy source connected to the solenoid is configured to de-energize after the media is fed in the gap between the solenoid piston and the ferrous plate, causing the bias element to force the solenoid piston to the down position and the magnet to press the media to the ferrous plate;
wherein, the programmable device is configured to systematically and incrementally increase the electrical energy to the solenoid, thereby incrementally increasing the retracting force on the solenoid piston towards the retract position until the retracting force is greater than the magnetic force pressing the solenoid piston to the media and the force from the bias element, causing the solenoid piston to return to the retract position;
wherein, the detector is configured to communicate that the solenoid piston is in the retract position to the programmable device;
wherein, the programmable device is configured to stop the incremental increase of electrical energy to the solenoid based upon information that the solenoid piston is in the retract position; and
wherein, the programmable device is further configured to correlate data on the incremental electrical energy increases to bring the solenoid to the retract position with distance data, the distance being the distance between the ferrous plate and an end of the magnet in contact with the media.
2. The apparatus of claim 1 further comprising a time measurement device in communication with the programmable device; wherein the electric energy source is a current source connected to the solenoid; wherein, the programmable device is configured to simultaneously start the time measurement device and to systematically and incrementally increase the current to the solenoid.
3. The apparatus of claim 2, wherein the current source is a constant ramp current driver.
4. The apparatus of claim 2, wherein the time measurement device is part of the programmable device; the programmable device being configured to measure time by program loops.
5. The apparatus of claim 2, wherein the time measured by the time measurement device is proportional to the systematic current increase.
6. The apparatus of claim 2, wherein the data is an algorithm which correlates the time measured by the time measurement device to media thickness.
7. The apparatus of claim 2, wherein the data is a table which correlates the time measured by the time measurement device to media thickness.
8. The apparatus of claim 1, wherein the electrical energy source is a voltage source, and wherein the apparatus further comprises a digital-to-analog converter (DAC) controlled by the programmable device and connected to the voltage source; wherein, the programmable device is configured to systematically supply in steps, digital numbers to the DAC;
wherein, the DAC is configured to convert the digital numbers to analog voltages at the voltage source, thereby supplying an incrementally increasing voltage to the solenoid in steps; and
wherein the data on the incremental electrical energy increases to bring the solenoid to the retract position is the last digital number supplied to the DAC.
9. The apparatus of claim 8, wherein the data is incorporated into an algorithm which correlates the last digital number output of the programmable device supplied to the DAC with media thickness.
10. The apparatus of claim 8, wherein the data is correlated to a table which includes a correlation of the last digital number output of the programmable device supplied to the DAC with media thickness.
11. The apparatus of claim 1, wherein the systematic increase in electrical energy is linear.
12. The apparatus of claim 1, wherein the systematic increase in electrical energy is a predetermined non-linear function.
13. The apparatus of claim 1, wherein the end of the magnet in contact with the media has a flat tip.
14. The apparatus of claim 1, wherein the solenoid piston has a second end opposing the end proximate to the ferrous plate; and wherein the detector is a contact switch, the second end contacting the contact switch when the piston is in the retract position.
15. The apparatus of claim 1, wherein the detector is a photo sensor.
16. The apparatus of claim 1, wherein the programmable device is selected from a dedicated logic circuit, a complex programmable logic device, a programmable array logic device, firmware, and a central processing unit.
18. The method of claim 17, wherein the step of positioning the magnet in the retract position is accomplished by the step of:
energizing the solenoid with a current source to a predetermined voltage, Vretract; and
wherein the step of pushing the magnet to the down position is accomplished by the steps of:
biasing the magnet with a compression spring arranged on the piston above the magnet; and
de-energizing the solenoid.
19. The method of claim 17, comprising, the step of detecting the piston in the retract position; wherein the step of detecting the piston in the retract position triggers a step of stopping the measuring step.
20. The method of claim 1, wherein the detecting step is accomplished by a detector selected from contact switches and photo sensors.

The present invention relates to an apparatus and method of measuring a media thickness, particularly on a printer.

Generally speaking, to achieve quality printing, knowing the thickness of the media being printed is important. If the printer can auto-detect the media thickness, then printing parameters can be set automatically, improving the print quality.

Therefore, a need exists for an apparatus and method of auto-detecting media thickness.

Accordingly, in one aspect, the present invention embraces an apparatus for determining the thickness of media.

In an exemplary embodiment the apparatus is comprised of a ferrous plate, a solenoid with a solenoid piston mounted above the ferrous plate, and a magnet disposed on an end of the solenoid piston proximate to the ferrous plate. The solenoid piston motion is perpendicular to the ferrous plate. The solenoid piston has a range of motion between a retract position where the magnet is a predetermined distance above the ferrous plate and a down position where the magnet presses on media fed in the gap between the solenoid piston and the ferrous plate. The predetermined distance provides a gap to feed media between the solenoid piston and the ferrous plate. The apparatus further includes an electrical energy source connected to the solenoid. The solenoid piston is forced with a retracting force to the retract position when the electrical energy source energizes the solenoid to a predetermined level. The solenoid piston also includes a bias element to keep the solenoid piston in the down position when the electrical energy source is not energizing the solenoid. The apparatus further includes a detector configured to determine when the solenoid piston is in the retract position. The apparatus also includes a programmable device in communication with the detector. The programmable device controls the electrical energy source. The electrical energy source connected to the solenoid is configured to de-energize after the media is fed in the gap between the solenoid piston and the ferrous plate, causing the bias element to force the solenoid piston to the down position and the magnet to press the media to the ferrous plate. The programmable device is further configured to systematically and incrementally increase the electrical energy to the solenoid, thereby incrementally increasing the retracting force on the solenoid piston towards the retract position until the retracting force is greater than the magnetic force pressing the solenoid piston to the media and the force from the bias element, causing the solenoid piston to return to the retract position. The detector is configured to communicate that the solenoid piston is in the retract position to the programmable device. The programmable device is configured to stop the incremental increase of electrical energy to the solenoid based upon information that the solenoid piston is in the retract position. The programmable device is further configured to correlate data on the incremental electrical energy increases to bring the solenoid to the retract position with distance data; the distance being the distance between the ferrous plate and an end of the magnet in contact with the media.

In another exemplary embodiment, the apparatus further includes a time measurement device in communication with the programmable device. The electric energy source is a current source connected to the solenoid. The programmable device is configured to simultaneously start the time measurement device and to systematically and incrementally increase the current to the solenoid.

In another exemplary embodiment of the apparatus, the current source is a constant ramp current driver.

In another exemplary embodiment of the apparatus, the time measurement device is part of the programmable device. The programmable device is configured to measure time by program loops.

In another exemplary embodiment of the apparatus, the time measured by the time measurement device is proportional to the systematic current increase.

In another exemplary embodiment of the apparatus, the data is an algorithm which correlates the time measured by the time measurement device to media thickness.

In yet another exemplary embodiment of the apparatus, the data is a table which correlates the time measured by the time measurement device to media thickness.

In another exemplary embodiment of the apparatus, the electrical energy source is a voltage source. The apparatus further includes a digital-to-analog converter (DAC) controlled by the programmable device and connected to the voltage source. The programmable device is configured to systematically supply in steps, digital numbers to the DAC. The DAC is configured to convert the digital numbers to analog voltages at the voltage source, thereby supplying an incrementally increasing voltage to the solenoid in steps. The data on the incremental electrical energy increases to bring the solenoid to the retract position is the last digital number supplied to the DAC.

In another exemplary embodiment of the apparatus, the data is incorporated into an algorithm which correlates the last digital number output of the programmable device supplied to the DAC with media thickness.

In another exemplary embodiment of the apparatus, the data is correlated to a table which includes a correlation of the last digital number output of the programmable device supplied to the DAC with media thickness.

In another exemplary embodiment of the apparatus, the systematic increase in electrical energy is linear.

In another exemplary embodiment of the apparatus, the systematic increase in electrical energy is a predetermined non-linear function.

In another exemplary embodiment of the apparatus, the end of the magnet in contact with the media has a flat tip.

In yet another exemplary embodiment of the apparatus, the solenoid piston has a second end opposing the end proximate to the ferrous plate. The detector is a contact switch; the second end contacting the contact switch when the piston is in the retract position.

In another exemplary embodiment of the apparatus, the detector is a photo sensor.

In yet another exemplary embodiment of the apparatus, the programmable device is selected from a dedicated logic circuit, a complex programmable logic device, a programmable array logic device, firmware, and a central processing unit.

In another aspect, the present invention embraces a method for automatic media thickness detection.

In an exemplary embodiment, the method includes the steps of: (i) positioning a magnet mounted on a solenoid piston above a ferrous plate in a retract position, (ii) placing media between the ferrous plate and the magnet in the retract position, (iii) pushing the magnet to a down position such that the magnet clamps the media to the ferrous plate, (iv) retracting the magnet to the retract position, (v) measuring the time for the piston to reach the retract position from the down position, (vi) correlating the measured time to known distance values, and (vii) determining the thickness of the media based on the correlating step. The solenoid being mounted so that the piston motion is perpendicular to the ferrous plate.

In another exemplary embodiment of the method, the step of positioning the magnet in the retract position is accomplished by the step of: energizing the solenoid with a current source to a predetermined voltage, Vretract. The step of pushing the magnet to the down position is accomplished by the steps of biasing the magnet with a compression spring arranged on the piston above the magnet, and de-energizing the solenoid.

In another exemplary embodiment, the method further comprises the step of detecting the piston in the retract position. The step of detecting the piston in the retract position triggers a step of stopping the measuring step.

In yet another exemplary embodiment of the method, the detecting step is accomplished by a detector selected from contact switches and photo sensors.

The foregoing illustrative summary, as well as other exemplary objectives and/or advantages of the invention, and the manner in which the same are accomplished, are further explained within the following detailed description and its accompanying drawings.

FIG. 1 schematically depicts in an exemplary embodiment, an apparatus for determining the thickness of media according the present invention wherein the electrical energy source is a current source, the solenoid being in the retract position.

FIG. 2 schematically depicts the exemplary embodiment of FIG. 1, with the solenoid in the down position.

FIG. 3 schematically depicts another exemplary embodiment of the apparatus for determining the thickness of media wherein the electrical energy source is a current source according to the present invention.

FIG. 4 schematically depicts in a flow chart the programmable device functions as a series of inputs and outputs to make the apparatus of FIG. 1 and FIG. 2 function in accordance with an exemplary embodiment of the present invention.

FIG. 5 schematically depicts in a flow chart, a method of determining the thickness of media in accordance with an exemplary embodiment of the present invention.

FIG. 6 schematically depicts in a flow chart, the steps to carry out the step of pushing the magnet into the down position of FIG. 3 in accordance with an exemplary embodiment of the present invention.

FIG. 7 schematically depicts another exemplary embodiment of the apparatus for determining the thickness of media wherein the electrical energy source is a voltage source according to the present invention.

FIG. 8 schematically depicts in a flow chart the programmable device functions as a series of inputs and outputs to make the apparatus of FIG. 7 function in accordance with an exemplary embodiment of the present invention.

The present invention embraces an apparatus for determining the thickness of media.

Referring to FIG. 1, in an exemplary embodiment, the apparatus (100) is general comprised of a ferrous plate (110), a solenoid (120) with a solenoid piston (122) mounted above the ferrous plate (110). The solenoid piston (122) range of motion is perpendicular to the ferrous plate (110). At the end of the solenoid piston (122) proximate to the ferrous plate (110), is disposed a magnet (130). The solenoid piston (122) has a range of motion between a retract position (124) where the magnet (130) is a predetermined distance above the ferrous plate (110), and a down position (shown in FIG. 2 as [126]) where the magnet (130) presses on media (112) fed in the gap (127) between the solenoid piston (122) and the ferrous plate (110). The predetermined distance provides a gap (127) to feed media (112) between the solenoid piston (122) and the ferrous plate (110). Also included in the apparatus (100) is a current source (140) connected to the solenoid (120). The solenoid piston (122) is forced with a retracting force to the retract position (124) when the current source (140) energizes the solenoid (120) to a predetermined current. The solenoid piston (122) has a bias element (128) to keep the solenoid piston (122) in the down position when the current source (140) is not energizing the solenoid (120). The apparatus further includes a detector (150) configured to determine when the solenoid piston is in the retract position (124). A programmable device (160) is provided in the apparatus (100). The programmable device (160) is in communication with the detector (150). Further, the programmable device (160) controls the current source (140). The apparatus further includes a time measurement device (170) in communication with the programmable device (160). In FIGS. 1 and 2, the time measurement device (170) is shown as a separate component. However, in an exemplary embodiment, the time measurement device (170) may be part of the programmable device (160). The programmable device may be configured to measure time by counting program loops. FIG. 2 shows the apparatus (100) in the down position (126). In FIG. 2, there is no gap between the magnet (130) and the media (112).

Continuing to refer to FIGS. 1 and 2, the current source (140) connected to the solenoid (120) is configured to de-energize after the media (112) is fed in the gap (127) between the magnet (130) on the solenoid piston (122) and the ferrous plate (110) in FIG. 1, causing the bias element (128) to force the solenoid piston (122) from the retract position (124) in FIG. 1 to the down position (126) in FIG. 2, causing the magnet (130) to press the media (112) to the ferrous plate (110). The programmable device (160) is configured to simultaneously start the time measurement device (170) and to systematically increase the current to the solenoid (120) via the current source (140). Thus, the retracting force is systematically increased on the solenoid piston (122) towards the retract position (124) until the retracting force is greater than the magnetic force pressing the solenoid piston (122) to the media (112) and the force from the bias element (128), thereby causing the solenoid piston (122) to return to the retract position (124). The programmable device (160) is further configured to stop the time measurement device (170) when the detector (150) determines that the solenoid piston (122) is in the retract position (124) and communicates this to the programmable device (160).

In an exemplary embodiment of the apparatus (100) as shown in the Figures, the bias element (128) is a compression spring arranged around the solenoid piston (122). However, in another exemplary embodiment, the bias element may simply be the weight of the solenoid (120) itself which forces the solenoid piston into the down position (126).

In another exemplary embodiment of the apparatus (100) the end of the magnet (130) in contact with the media (112) has a flat tip (131) as shown in the Figures.

In FIGS. 1 and 2, the programmable device (160) may be a dedicated logic circuit, a complex programmable logic device, a programmable array logic device, firmware, or a central processing unit.

In another exemplary embodiment, the detector (150) is a contact switch. One end of the solenoid piston (122) touching the contact switch when the solenoid piston (122) is in the retract position (124) and closing the contact switch. The contact switch is part of a circuit which, when complete, will communicate this condition to the programmable device (160).

In another exemplary embodiment, the detector (150) is a photo sensor.

In an exemplary embodiment of the apparatus (100) as shown in the Figures, the systematic increase in current supplied to the solenoid (120) by the current source (140) is linear. In another exemplary embodiment, the current supplied is a predetermined non-linear function.

In an exemplary embodiment, the current source (140) may be a constant ramp current driver. The programmable device (160) controls the systematic increase of the current to the solenoid (120) with the constant ramp current driver.

For example, referring now to FIG. 3, an apparatus (200) in another exemplary embodiment of the invention is shown. The solenoid structure, solenoid (120), solenoid piston (122), bias element (128), and magnet (130) with a flat tip (131) are identical to FIGS. 1 and 2. In the present FIG. 3, the programmable device is a central processing unit (CPU) (260) which is in communication with the detector (250) and the current source (240). The detector (250) is shown as a contact switch which will complete a circuit (252) when the solenoid piston (122) is in the retract position. When the circuit (252) is complete, this information is transmitted to the CPU (260).

In the present FIG. 3, the current source (240) is a constant ramp current driver controlled by the CPU (260).

The time measurement device (270) is incorporated in the CPU (260) in the present FIG. 3, but may be a discrete device as in the previous Figures. As discussed hereinabove, the programmable device (260) may be configured to measure time by counting program loops.

FIG. 4 illustrates the functions of the programmable device (160, 260) according to exemplary embodiments shown in FIGS. 1, 2, and 3 of the present invention. The Figure shows the functions as outputs (400) in response to inputs (300) to the programmable device (160, 260). For example, when media is fed (input 310) into the apparatus on the ferrous plate, this information is communicated to the programmable device (160, 260). The programmable device (160 260) is configured to communicate (output 410) to the current source to de-energize the solenoid. Input (310) may be based upon a sensor (not shown) sensing the media, and the sensor being in communication with the programmable device (160), resulting in the programmable device (160, 260) causing output (410). Alternatively, in another exemplary embodiment, an operator of the apparatus (100, 200) may provide input 310 that media has been fed to the programmable device (160, 260). As discussed hereinbefore, once the current source (140) de-energizes the solenoid (120), the biasing element (128) forces the solenoid piston into the down position. The programmable device (160, 260) has simultaneous outputs (420) to start a systematic increase in current in the current source (140) and (430) to start the time measurement device (170, 270). The detector (150, 250) sensing the solenoid piston is in the retract position (124) is input (320) to the programmable device (160, 260), and results in the output (440) of stopping the measurement device (170, 270).

In an exemplary embodiment, the programmable device (160, 260) is configured to correlate the time measured by the time measurement device (170, 260) with a distance, the distance being the distance between the ferrous plate (110) and an end of the magnet (130) in contact with the media (112). This is shown in FIG. 4 as output (450). The time/distance correlation data (input 330) may be accessed within the programmable device (160, 260), that is, the programmable device (160, 260), for example, in one exemplary embodiment, has access to data which correlates the time measured by the time measurement device (170, 270) to media thickness. In another exemplary embodiment, the programmable device (160, 260) has access to an algorithm which correlates the time measured by the time measurement device to media thickness.

In another exemplary embodiment, the time measured by the time measurement device is proportional to the systematic current increase.

In another aspect, the invention embraces a method for automatic media thickness detection. Referring now to FIG. 5, the method (500) is shown in a flow chart.

In an exemplary embodiment, the method (500) is comprised of the steps of: (510) positioning a magnet mounted on a solenoid piston above a ferrous plate in a retract position; (520) placing media between the ferrous plate and the magnet in the retract position; (530) pushing the magnet to a down position such that the magnet clamps the media to the ferrous plate; (540) retracting the magnet to the retract position; (570) measuring the time for the piston to reach the retract position from the down position; (580) correlating the measured time to known distance values; and (590) determining the thickness of the media based on the correlating step.

In the (510) positioning step, the solenoid is mounted so that the piston motion is perpendicular to the ferrous plate.

In another exemplary embodiment of the method (500), the step (510) of positioning the magnet in the retract position is accomplished by the step of (511) energizing the solenoid with a current source to a predetermined voltage, Vretract.

In another exemplary embodiment, the method (500) further may comprise the step of (550) detecting the piston in the retract position, which triggers an additional step of (560) stopping the measuring step. The (550) detecting step may be accomplished for example, by a detector like a contact switch or a photo sensor.

Referring now to FIG. 6, step of (530) pushing the magnet to the down position from FIG. 5 may be accomplished by the steps of (531) biasing the magnet with a compression spring arranged on the piston above the magnet, and (532) de-energizing the solenoid.

Advantageously, the method of FIG. 5 and FIG. 6 may be accomplished with the apparatuses discussed and described in relation to FIGS. 1-4.

The present invention further embraces an apparatus to measure the thickness of media using voltage steps.

Referring now to FIG. 7, in an exemplary embodiment, the apparatus (600) includes, as in the previous figures, the solenoid (120) with solenoid piston (122) oriented with the solenoid piston's (122) range of motion perpendicular to the ferrous plate (110). The solenoid piston (122) has a range of motion from a retract position away from the ferrous plate (110) to a down position where a magnet (130) on the end of the solenoid piston (122) proximate to the ferrous plate (110) touches the ferrous plate (110) or media (112) fed between the magnet (130) and the ferrous plate (110). Advantageously, the magnet (130) has a flat tip (131). A detector (250) is provided to sense when the solenoid piston (122) is in the retract position. As in embodiments discussed hereinbefore, the detector (250) may be a contact sensor, a photo sensor, or the like. A voltage source (640) is provided to supply voltage to the solenoid (120) to move the solenoid (120) to the retract position. A programmable device (660) is provided and is in communication with the detector (250). The programmable device may be a CPU as shown in the Figure, but could also be a dedicated logic circuit, a complex programmable logic device, a programmable array logic device, firmware or the like. The detector (250) communicates to the programmable device (660) when the solenoid piston (122) is in the retract position. The programmable device (660) outputs a digital signal at the digital signal or number output (650) to a digital-to-analog converter (DAC) (630). The DAC (630) in turn converts the digital signal to a voltage in the voltage source (640) to supply the solenoid (120). When media (112) is fed into the gap between the magnet (130) and the ferrous plate (110), the programmable device (660) is configured to output a digital signal at the digital signal or number output (650) to the DAC (630), and thus to the voltage source (640) to cause the voltage supplied to the solenoid (120) to be 0 volts. This communication of media feed may be supplied by a sensor (not shown) in communication with the programmable device (660) or by an operator of the apparatus (600). The solenoid piston (120) is provided with a bias element (128) which causes the solenoid piston to move to the down position when the supplied voltage is 0 volts. Once the solenoid piston (122) is in the down position, the programmable device is configured to cause the voltage source (640) to systematically, preferably in steps, to incrementally increase the voltage to the solenoid (120). This can be accomplished by the programmable device (660) providing a series of digital signals at the digital number output (650) to the DAC (630). The DAC (630) converts the digital signals to incrementally increasing analog voltages for the voltage source (640) to supply to the solenoid (120). The incrementally increasing voltage supplied to the solenoid (120) increases the retracting force on the solenoid piston (122) towards the retract position until the retracting force is greater than the magnetic force pressing the solenoid piston (122) to the media (112) and the force from the bias element (128), causing the solenoid piston (122) to return to the retract position. The detector (250) communicates the solenoid piston's (122) return to the retract position to the programmable device (660). The programmable device (660) stops the voltage increase via a signal from the digital number output (650) to the DAC (630). The programmable device (660) can correlate the last digital output number to a media thickness based upon access to data, a table or an algorithm which correlates voltage measurement to media thickness.

FIG. 8 depicts the input/output flow for the programmable device (660) for the embodiment described in conjunction with FIG. 7. The components in FIG. 7 of the apparatus (600) will be referred to in FIG. 8.

In FIG. 8, the Inputs (700) to the programmable device (660) and the Outputs (800) from the programmable device (660) are depicted in a flow chart. When media (112) is fed (Input 710) into the apparatus (600) on the ferrous plate (110), this information is communicated to the programmable device (660). The programmable device (660) is configured to cause the voltage to the voltage source (640) to be 0 Volts via the DAC (Output 810), de-energizing the solenoid (120). Input (310) may be based upon a sensor (not shown) sensing the media (112), and the sensor being in communication with the programmable device (660), resulting in the programmable device (660) causing Output (810). Alternatively, in another exemplary embodiment, an operator of the apparatus (600) may provide the information Input 710 to the programmable device (660) that media (112) has been fed. As discussed hereinbefore, once the voltage source (640) de-energizes the solenoid (120), the biasing element (128) forces the solenoid piston (122) into the down position. The programmable device (660) starts Output (820) to systematically increase the Digital number from the digital number output (650) to the DAC (630), which in turn systematically and incrementally increases the voltage to the solenoid (120). Due to the incremental increase in voltage, the solenoid piston (122) eventually reaches the retract position. The detector (250) sensing the solenoid piston (122) is in the retract position provides Input (720) to the programmable device (660), and results in the programmable device (660) Output (830) of stopping the increase in voltage. The programmable device (660) receives Input (730), which may be internal to the programmable device (660), of a digital number correlation to distance of solenoid piston retraction. Input (730) prompts the programmable device (660) to give Output (840): the media thickness based upon the last digital number output (820) before detector (250) Input (720) and the correlation data. Input (730) may be the result of a correlation of the last digital number output from the programmable device (660) to media thickness via known values stored in a table in the programmable device (660). Alternatively, in another exemplary embodiment, the last digital number output may be entered into an algorithm resident on the programmable device (660) which correlates the last digital number output to media thickness.

To supplement the present disclosure, this application incorporates entirely by reference the following commonly assigned patents, patent application publications, and patent applications:

In the specification and/or figures, typical embodiments of the invention have been disclosed. The present invention is not limited to such exemplary embodiments. The use of the term “and/or” includes any and all combinations of one or more of the associated listed items. The figures are schematic representations and so are not necessarily drawn to scale. Unless otherwise noted, specific terms have been used in a generic and descriptive sense and not for purposes of limitation.

Spargur, David

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